Recovery time after localized perturbations in complex dynamical networks
| Autor: | Anshul Choudhary, Jürgen Kurths, Chiranjit Mitra, Reik V. Donner, Tim Kittel |
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| Rok vydání: | 2017 |
| Předmět: |
networked dynamical systems
Dynamical systems theory FOS: Physical sciences General Physics and Astronomy Network topology Topology Dynamical system 01 natural sciences Measure (mathematics) 010305 fluids & plasmas nonlinear dynamics dynamical timescales 0103 physical sciences ddc:530 complex systems 010306 general physics Physics Complex network Nonlinear Sciences - Chaotic Dynamics 530 Physik A priori and a posteriori Node (circuits) Transient (oscillation) Chaotic Dynamics (nlin.CD) transient stability against shocks synchronization |
| Zdroj: | New Journal of Physics. 19:103004 |
| ISSN: | 1367-2630 |
| DOI: | 10.1088/1367-2630/aa7fab |
| Popis: | Maintaining the synchronous motion of dynamical systems interacting on complex networks is often critical to their functionality. However, real-world networked dynamical systems operating synchronously are prone to random perturbations driving the system to arbitrary states within the corresponding basin of attraction, thereby leading to epochs of desynchronized dynamics with a priori unknown durations. Thus, it is highly relevant to have an estimate of the duration of such transient phases before the system returns to synchrony, following a random perturbation to the dynamical state of any particular node of the network. We address this issue here by proposing the framework of \emph{single-node recovery time} (SNRT) which provides an estimate of the relative time scales underlying the transient dynamics of the nodes of a network during its restoration to synchrony. We utilize this in differentiating the particularly \emph{slow} nodes of the network from the relatively \emph{fast} nodes, thus identifying the critical nodes which when perturbed lead to significantly enlarged recovery time of the system before resuming synchronized operation. Further, we reveal explicit relationships between the SNRT values of a network, and its \emph{global relaxation time} when starting all the nodes from random initial conditions. We employ the proposed concept for deducing microscopic relationships between topological features of nodes and their respective SNRT values. The framework of SNRT is further extended to a measure of resilience of the different nodes of a networked dynamical system. We demonstrate the potential of SNRT in networks of R\"{o}ssler oscillators on paradigmatic topologies and a model of the power grid of the United Kingdom with second-order Kuramoto-type nodal dynamics illustrating the conceivable practical applicability of the proposed concept. Comment: 21 pages, 7 figures |
| Databáze: | OpenAIRE |
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